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Main Authors: Seo, Yu-Seong, Ha, Teawoo, Yoo, Ji Hee, Kim, Su Jae, Lee, Yousil, Kim, Seungje, Kim, Young-Hoon, Cha, SeungNam, Kim, Young-Min, Jeong, Se-Young, Hwang, Jungseek
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2509.20644
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author Seo, Yu-Seong
Ha, Teawoo
Yoo, Ji Hee
Kim, Su Jae
Lee, Yousil
Kim, Seungje
Kim, Young-Hoon
Cha, SeungNam
Kim, Young-Min
Jeong, Se-Young
Hwang, Jungseek
author_facet Seo, Yu-Seong
Ha, Teawoo
Yoo, Ji Hee
Kim, Su Jae
Lee, Yousil
Kim, Seungje
Kim, Young-Hoon
Cha, SeungNam
Kim, Young-Min
Jeong, Se-Young
Hwang, Jungseek
contents In the design of optical devices and components, geometric structures and optical properties of materials, such as absorption, refraction, reflection, diffraction, scattering, and trapping, have been utilized. Finding the ideal material with certain optical and geometric characteristics is essential for a customized application. Here, we fabricated unoxidizable achromatic copper films (ACFs) on Al2O3 substrates utilizing an atomic sputtering epitaxy apparatus. ACFs are made up of two regions vertically: a comparatively flat layer region and a three-dimensional (3D) porous nanostructured region on top of the flat region. The measured specular reflectance displayed low-pass filter behaviour with a sharp cutoff frequency in the infrared spectrum. Furthermore, the measured diffusive reflectance spectra showed light-trapping behaviour in the spectral region above the cutoff frequency, where there are no known absorption mechanisms, such as phonons and interband transitions. A focused ion beam scanning electron microscope was utilized to study the thin film's nanostructured region through 3D tomographic analysis in order to comprehend the phenomena that were observed. This work will shed fresh light on the design and optimization of optical filters and light-trapping employing porous nanostructured metallic thin films.
format Preprint
id arxiv_https___arxiv_org_abs_2509_20644
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Stray light in 3D porous nanostructures of single crystalline copper film
Seo, Yu-Seong
Ha, Teawoo
Yoo, Ji Hee
Kim, Su Jae
Lee, Yousil
Kim, Seungje
Kim, Young-Hoon
Cha, SeungNam
Kim, Young-Min
Jeong, Se-Young
Hwang, Jungseek
Optics
Materials Science
In the design of optical devices and components, geometric structures and optical properties of materials, such as absorption, refraction, reflection, diffraction, scattering, and trapping, have been utilized. Finding the ideal material with certain optical and geometric characteristics is essential for a customized application. Here, we fabricated unoxidizable achromatic copper films (ACFs) on Al2O3 substrates utilizing an atomic sputtering epitaxy apparatus. ACFs are made up of two regions vertically: a comparatively flat layer region and a three-dimensional (3D) porous nanostructured region on top of the flat region. The measured specular reflectance displayed low-pass filter behaviour with a sharp cutoff frequency in the infrared spectrum. Furthermore, the measured diffusive reflectance spectra showed light-trapping behaviour in the spectral region above the cutoff frequency, where there are no known absorption mechanisms, such as phonons and interband transitions. A focused ion beam scanning electron microscope was utilized to study the thin film's nanostructured region through 3D tomographic analysis in order to comprehend the phenomena that were observed. This work will shed fresh light on the design and optimization of optical filters and light-trapping employing porous nanostructured metallic thin films.
title Stray light in 3D porous nanostructures of single crystalline copper film
topic Optics
Materials Science
url https://arxiv.org/abs/2509.20644